Feeding machine



March 4, 1958 J. w. BATCHELDER 2,825,489

FEEDING MACHINE Filed June 13, 1952 l0 Sheets-Sheet 1 b JNVENTOR.

mass 1 n. BATOHELDER 45 ATTORNEYS March 4, 1958 J. w. BATCHELDER v FEEDING MACHINE 10 Sheets-Sheet 2 Filed June 13. 1952 T m w.

JAMES I EATOHELDER ATTORNEYS March 4, 1958 J. w. BATCHELDER FEEDING MACHINE 1O Sheeis-Sheet 3 Filed June 13. 1952 INVENTOR.

JAMES m EATGHELDER 2/ $1 ArromL-rs J. w. BATCHELDER FEEDING MACHINE March 4, 1958 10 SheetsSheet 4 Filed June l3, 1952 INVEN TOR. JAMES M BATE/[ELDER %?//{PA%%(% ATTORNEYS March 4, 1958 J. w. BATCHELDER FEEDING MACHINE 10 Sheets-Sheet 5 Filed June 13, 1952 FIG. /0

FIG. 9

FIG.

INVNTOR.

. JAMES m BATOHELDER ATTORNEYS March 4, 1958 J. BATCHELDER FEEDING MACHINE 1O Sheets-Sheet 6 Filed June 13, 1952 IN V EN TOR. .14 MES m BATCHEL 05/? rm/mus March 4, 1958 J. w. BATCHELDER ,8 5, 89

FEEDING MACHINE Filed June 15. 1952 10 Sheets-Sheet 7 INVENTOR. 1 m BATCH/ELDER FIG. 25

-March 4, 1958 J. w. BATCHELDER 2,825,489

FEEDING MACHINE Filed June 13. 1952 10 Sheets-Sheet 8 NN 6R MW 6R ll I. Q

H mm R 6 mM/Mm N G E mfijm 0v m B m W T J 4 a M a 1 w mom vmm Nmw Marh 1953 I J. w. BATCHELDER 2,82

FEEDING MACHINE l0 Sheets-Sheet 9 Filed June 13, 1952 INVENTOR. JAMES 144 BATCHELDEE 197' Toff/f Y March 4, 1958 J. w. BATQHELDER FEEDING MACHINE 1O Sheets-Sheet 10 Filed June 15, 1952 INVENTOR.

JAMES w. B4 m/a 052 ATTOF/Vf) I United States Patent FEEDING MACHINE James W. Batchelder, Ascutney, Vt., assignor, by mesne assignments, to Batcheider Engineering Co., Inc, Springfield, Vt., a corporation of Vermont Application June 13, 1952, Serial No. 293,303

9 Claims. (Cl. 221-160) This invention relates to improvements in automatic feeding machines, and in particular to feeding machines of the type whereby screws, nails, nuts, rivets or other such work pieces or blanks therefor are fed individually through a feeder discharge track to counting, slotting, or thread rolling machines or the like.

' Track type feeding machines usually include a hopper into which work pieces are loaded in bulk, a slotted teed track or channel to align the work pieces and to discharge them individually and in definite orientation to a machine being fed, means on the feed track for guiding the work pieces into the slot in proper position, and a transfer mechanism whereby the work pieces are delivered from the hopper to the feed track guides at a controlled rate. Such machines of the prior art have been afliicted with various disadvantages such as jamming of work pieces in moving parts of the transfer mechanism, undue wear of such moving parts by the work pieces or metallic debris accompanying the work pieces, and limitation of feeding rates due to escape of work pieces delivered to the track guides or due to mutual interference of work pieces at the guides. Further, the adjustments and changes required in the machine for handling various sizes and shapes of work pieces have not been readily effected in such machines.

Hence, an object of the present invention is the provision of a feeder machine wherein jamming andwear of the transfer mechanism is avoided. Another object is the provision in a feeder machine of a feed track mechanism including work piece guides adapted to handle work pieces at high feed rates. Another object is the provision of a feeding machine adapted to feed various types and sizes of'work pieces. Other objects and advantages of the invention will appear from the following description and the drawings, wherein Fig. 1 is a plan view of the machine with the driving mechanism shield removed;

Fig. 2 is an elevation view of the discharge end of the machine;

Fig. 3 is a side elevation of the machine of this invention with. certain parts broken away to show the operating mechanism more clearly;

Fig. 4 is a sectional view taken along the line 4-4 in Fig. 2;

Fig. 5 is a detail sectional view taken along the staggered line 55 in Fig. 4 to show the manner of mounting the lifting ring in the frame;

Fig. 6 is a detail of the feed hopper outlet in section taken at 6--6 in Fig. 1;

Figs. 7 and 8 are fragmentary sections taken at the lines 7-! and 88 in Fig. 3 to show in detail the manner of mounting. the feed tracks for adjustable spacing;

Fig. 9 is a sectional detail taken at the line 9-9 in Fig. 3 showing details of the feed track structure;

Fig. 10 is a section of the discharge portion of the feed tracks taken at the line 16-10 in Fig. 3;

Fig, ll is similar to Fig. 9, but shows the use of a Fig. 12 is a third form of interchangeable baflied feed track;

Fig. 13 is a detail showing a modification of the vibrating feed track actuating means;

Fig. 14 shows the use of a revolving brush attachment on the machine for feeding top-heavy nuts or similar items;

Fig. 15 is a sectional detail of the brush attachment taken substantially along the line 15-15 in Fig. 1'4;

Fig. 16 is a side view similar to Fig. 3 showing the arrangement of a conveyor belt type feed track with certain parts broken away or omitted which are not necessary for disclosure of the structure;

Figs. 17, 18 and 19 are fragmentary details taken-in section in Fig. 16 along the lines 17-17, 18-18 and 19-19 to show details of the conveyor belt mounting and driving structure;

Fig. 20 is a fragmentary view showing the second form of lift ring;

Fig. 21 is a fragmentary view taken along the line 21-21 in Fig. 20;

Fig. 22 lS a fragmentary side view of the ring of Figs. 20 and 21;

Fig. 23, similar to Fig. 22, shows a modification of the lift ring or rigures Zu-AZ;

Fig. 24 is a fragmentary view showing the inner surface of a third form or hit ring for handling nails;

Figs. 25 and 26 are sectional details of Fig. 24 taken along the lmes 25-2: and zo2o therein;

hg. 27 1s a side elevation of the machine adapted for feeding items without individual orientation;

mg. 26 1s a fragmentary view partially in section taken along the lines Z6-Zi;

rig. L7 18 a fragmentary perspective view of a modification or the vibrating teen trough shown in big. 28;

Fig. 30 1s a side view of a teeder having a belt driven eccentric type track actuating unit; and

rig. 31 1s a detail view of the actuating unit, taken partly in sec-non along the line 31-31 in mg. 30.

1n the high speed automatic hopper teed machine shown in rigs. l to 4, a hrung ring unit 40 powered by a driving mecnanlsm e1 transports work pieces, charged in bulk to hopper 42, from the hopper to an aligning teed mechanism l5, which delivers the work pieces individually and in oeiimte orientation at its discharge end for presentation to a machine being fed thereby. The lifting ring unit 40 comprises a hollow square member 45 having a large circular opening in each or me two opposite square faces and annular end plates 41, 4:5 bolted respecnvely to the hopper and discharge sides of the member as to form therewith a hrtmg ring housing for the open end ht'ting ring 46. As may be seen more clearly in Figs.

4 and 5, the lifting ring 46 has a channel shaped cross.

section providing inwardly projecting end flanges 50, 51 forming with partitions 52 a plurality of lifting pockets 53 spaced about the inner circumference of the ring. To avoid a central shaft and spider supports extending to the ring, which usually interfere with the movement of work pieces, the ring is rotatably supported between the end plates 47, 48 by two of the housing sets of trunnion rollers 54 hearing on its outer cylindrical surface, each set being. mounted to the inner surface of the corresponding end plate. The ring end flanges 50, 51 are provided to prevent jamming of work pieces against the stationary end plates 47, 48 and also to prevent abrasion of the plates by the.

47 and 48 respectively, extending inwardly over the flanges 50, 51 to prevent chips and other debris from The lifting ring is provided on its outer circumference 7 with .a'central groove 58 to receive a V-belt 59 extending through :openin'gs in the frame .frorn the' driving mechanlsm .41. The end plate 48 is secured to the frame member 45 by bolts 60passed through the'slotted ears "61 into the frame member. The plate 47 is similarly secured to" the frame by bolts '62 passed through the ears 63, whereby the end plates may be.readily 're'movedand r .replaced for changing the liftingring. 'fo prevent work 1 pieces inthe .lift. compartments from pr'ojectin'g through the plane of [the opening in end plate 48 and possibly' catching under part of track assembly 97, an inward Iguard extension .4812 terminating above thetrack. assembly; and 'having a spiral inwardly receding edge, is provided. on;plat e 48'adjacent: the upper end of'the track'assembly;

' -The driving unit141 (Figs. 1 audit) comprises'a motor 65, a pair of pulleys 66 and 67 keyed to a shaft 68 jour-I naled. inazbracket .69'fixed to thetop of theframe 45,

' thelmotor pulley; 70 through V-belt '71 drivingctifi. Tand hence67: which isconnected to the lift ring by'V-belt 59..

Preferablyypulleys 66- and 70 are variable pitch'V-belt' pulleys for spee'd range control or .they maylberemovable, so that by changing them the speed of the'lifting accurate count. r a a 3 V The feed track assembly 97 iis'suspended at'its upper and lower, ends for endwise oscillationbygspring plates 1 s 110L115 eachbolted to thehousingjBt). Right :angle 7 bracket pieces 107, 108- affixedbyione'leg to. the track bars 101', 102 respectively, have .Jthe otherjlegs-fittedi within the groove of a'channel piece 109- secured trans-. V 7 .v ersely at the upper end of spring 'plate; 110: Aboltj. 111 passed through bracket 107, channel 109 and spring lltl; holds the bar 101 at afixed SPQCiIlgffl'OlIl the annular-{J plate 48, whilethe bolt 112 with wingnut'113.passed; through bracket- 108 and through :the align'ed. .slots';in

.25 ring may be varied. .To effect. speed control withvarij able pitch pulleys, or to facilitate changing the pulleys,. V the motor 65 is movably mounted .foradjustment toward and away from the pulley bracket 69 by a carriage74. riding-on .rod 73 andengaging an. adjusting screw .75; J rotatable by hand wheel76 injournal. brackets '77, 79 on the frame 45.;. Other types of. speed control may, .of

course, be used. :lhe entire driving mechanism .is en-. 7

closed by a shield'78'bolted tothe' top of. the frame455. lThe hopper 'unit 42, open at thetop and having bottom 8 0 slanted toi,,a. lateral opening .81 to....discharge1tolthe lifting ring, ishinged to the annulanplate 47atone end. by hinge members.82, 83 and'at theotherend is .heldin 1 closed position against the plate-byalocking nut ;and lug 84.and;plate stud,85; To control theflowof work pieces 7 through opening 81 to thelift ring, a plate. 86. slid'ably mounted to the hopperwall is securediin adjustedposifition by wing nuts .87 on the" bolts.,88. extending through thehopperwallandtheverticalplateslots 89. The'edge 8la'of theopening ;8.1, toWard.theiascending side .of ,.the.

ring, recedes in spiralform; from ,the;;lift1ringto 1 mergeinto. the top edge ioflthe; opening, .whereby. any. work. pieces projecting from the lift 'ring' are. prevented from :Qatchjng beneath the 'top. edgeLofthe opening.

' I Extendinglaterallyfrom and integral withthe plate. 48-isa hopperrlike enclosure 90-forming1a housingand mounting for. the, feed track'mechanism- 43; the bottom;

91 ofwhich'is' curved or. sloped downwardly towards'the "opening of the annular ring 48.2to return toj the lifting ring work pieces rejected .Oresca in'g-from the feeding mechanism. Toreceive work pieces dropped from'the V I compartments 53 of the lifting ring at the uppermost posi-f tion thereof anddeliverthem to the feed mechanism, 21

chute 93 is provided in the form of affianged tray mem s V l annulanplate 48 and extending. substantially across the 7 her mounted by a bracket 94'to' the'upper portion of the width of the'frame 45 and of the'feed track assembly .97.

The chute slanted downwardly and to one side to bring theldischarge opening 95-near'to the upperend of the ,fcedtrack; Y -1 a "The feed mechanism the. general" disposition of ,whichimaybst be seen in 'Fig.--3,"comprises the feed; 1 track assembly"97 extending parallel to the plane of rotation of the' liftsring.through openings in the housing Maud mountedthereto forendwise vibration, an electro-- magnetic track actuating unit, '98 including an electric control unit .99, and a rejector mechanism" 100 for re moving misaligned work pieces from {the track; The. feed track,mechanism and mounting structure. shown in' detani rigs. '7' to 9, comprisea pair of parallel bars 101 maximum feedrateis increased. n I

' Skirts 120 and 121 with overlappingbottomfianges secured along the bottom edges of'thetraek barsito'p'rpj I vide 'a trough-like shieldjfor..the.lower:. endsof wen pieces feeding down thetrack,mechanism to'prevent in-f. M terference by work pieces in thelen'closure 190. 'Alsog'i since the lower endsofthefskirts openthrough the wall' of housing 90, any debris delivered withgwork piejces to v the'trackis discharged outside the" housingiso thatjthe f skirts have the further'function'of continnouslyremoying V abrasive foreign material from-the machine; {The brackets 124.;on thebar 101 (see Fi'g lQ) suspend'the'holdingj' bar.105 by studsIZSeXtending ,upwardly from the bar:

Fig.9 shows the disposition and mounting'of the .wing I V or guide baffies 103, '10 4to the'trackrbars. '.'These.bafi ies.f v are provided'with corrugationswhiehhinderv movement- 1 of the work pieces. lengthwise of the baflles; direct. them 7 towards the slot and with the endwise oscillationof'the track assembly hereinafter described, serve to separate, and disentangle work pieces delivered fromxthe chute'jfis a Thesebaffles are sloped inwardly. to 'iguideflwork piecesfl toward the track slot,'the. anglefof flare or slope toward V the slot being preferably about 153' so that the work pieces= roll toward the track slot-.but do notyslide lengthwise. 7 thereof. .Ricocheting 'of workpieces from the ,track' mechanism when dropped thereonfrom sam 9s, which a I usually causes .escape from the traek me chanism -and i V Vwhich'cannotbe overcome by increasing the lifting rate due to mutual interference of excess work pieceson'thej bafiles, isminimized byus'e of. the batiieand traek angles. described. Hence a highipercentageqofwork piec s-ea;

track. slot,lsofthat and spaced to provide feed in the'enclosure thev'inclination of the feed t'ra'ck is' of sucha magnitude as willpermit downward movement of workpieces when the track is vibrated endwise as' V hereinafter described ,-'but.not to.allow free sliding when l .7 the track is stationary-1 A. track inclination from 0, up. V 1 to about 201gene'rallyfmay,belused.V Ihe slope ofithe'f f feed'track outside the enclosure; that is, of lo vve r reaches 10117 and 102b may beigreater and a holding liar 105 n is mounted' thereabove:torcontroljthe movementot thei f workpieces by retaining .themonthe track and pre vent- 7' ing the heads thereof from overlapping. Preferablyihe I top surfaces'of'th e bars are beveled inwardly along the 7 lower or'discharge portions 101b, 102b (see Fig. 10); This. increased slope is-preferable where-the feederf is used witha photocellcounten'since it causes-spacing-to' 7 thereby allowing .a more develop between work pieces,

the brackets 108 and '117 of the movable bar lilz.

livered by the lifting ringfind the.

through each bracketf124 and held by means of the wing nuts 126 to provide for/height adjustment'of the "bar,

slot to accommodate and align work pieces and having :wingsor bafilesj103 104. respectively, afiixed on the upperportion thereof beneath' the chute93 to direct workpieces into the slot; V Pref- 1 .erably these baffles are corrugated rather thanfiatlf With-g e se gee a coil s rin 121 being" di eased:tietwieefi the l? ket and the holdingb'an Rre'ferably 'a'c'ollar- 123; having a flanged end hearing on' the 'braeket 124 isdnpe sed 'abeufi thestud125within the coil spring to ste'ady' the-bari The actuating mechanism for: the track coinp'rises an electromagnet 130 mounted- 5y a bracket to th'eend plate 48 and anal-mature bar"131 bolted to the spring plate 110. The motion induced by the actuating mech-' anism differs from that utilized-in many feed tracks to' overcome static friction, for when the armature is-attracted by the electromagnetthe track assembly 97 is drawn sharply in an endwise direction against the re-' sisting force of the springs 110, 115, and when released,

the springs move the track mechanism back at'a rela'- before the opposite spring induced movement of the track.

is. efiected, so that with rapid vibration the parts move quickly down the track. The control unit 99 may con tain a suitable timing device or circuit to supply a timed interrupted electric current to the-'electromagnet, a con; trol switch and rheostat or other control meanswhereby the current to the electromagnet is regulated to determine the amplitude of endwise oscillation of the track assembly.

The rejector mechanism assembly 100, serving to cast from the track into the housing 90 those work pieces which are not properly aligned in the slot, comprises a; circumferentially slotted and notched kicker wheel 135 rotating with a pulley shaft 136 journaled in arm' 137 of a right angle bracket plate and an electric motor 138 mounted on the other arm 139 of the bracket for driving the wheel through motor pulley 140,. pulley 141, on shaft 136 and pulley belt 142. The bracket plate is pivoted near its apex to a block 145 slidably mountedto the outside of housing 90 by a bolt and slot connection. Close adjustment of the height of the kicker wheel relative to the track is provided by stud 147 on the upper end of the block 145 extending through a perforated lug 148 on the housing 90, the stud and block being. raised and lowered by awing nut 149. Preferably a spiral spring 150 is interposed between the sliding block 145 and the lug 148 to urge the entire assembly downwardly. The upper end ofholding bar 105 may be formed into a tongue projecting into the circumferential groove of the rejector wheel-135, so that no gap occurs between the wheel and the bar wherein work pieces might become malpositioned.

By beveling the top surface of track bars 101, 102 outwardly between the end of the bafiles and the wheel- 135, the majority of those work pieces, tending to ride athwart the top of the track, are caused to drop offthe track to the bottom of enclosing hopper 90 for return to the left ring, thereby decreasing the load on the rejector wheel. With the lower or discharge reaches of the track bars more sharply inclined than the upper reaches, and with the apex or hump 19 formed at the junction of the two reaches disposed adjacent to and just in front of the rejector wheel, such work pieces, as by reason of proportion might pass the wheel on a straight track even though not suspended in the slot, are brought into contact with the wheel and rejected in passing over the apex portion of the track.

In operation, the lifting ring picks up work pieces flowing from the hopper through the opening 81 and carriesthem' upwardly to a position above the chute 93 where they are released to the chute as the compartments 53 swing into an inverted position. The work pieces-sliding down the chute discharge'upou the cor rti'gated ti'afiiesfor 'win'ge 103', l04 'and under the de=--- seribed vibrating motion of the mechanism98 are sepa-- Any workpieces: which escape from the track or'bafiles are. T carriedlay the bottom slope of the enclosure back to' the lifti'ng rin'gi The heads of screws, nails or other" such work piecesbearing on the top be'veled' edges off the bars, suspend the body'of the work pieces betweenthe slots in seriallyaligned'relation as the vibrating actionrated aiid Worked into the slot between the bars;

carries th'e workpieces down towards the kicker wheel under which the heads pass when the pieces are properly: suspended to feed into the lower external end portion of the feedtrack beneath the holding bar 105. Any work pieceswhich travel down the track in any but properly 1 suspended position either fall off the beveled top before reaching kicker Wheel or are rejected by the Wheel and tossed inwardly into the enclosure to returnto' the lifting wheel.

The feeder machine maybe adapted to a double discharge feed by utilizing the hopper 42 to mount a second feed track, feed track actuating assembly, and rejector mechanism. In that case the chute 93 would be provided with a second discharge portion 95 extending over the second feed track assembly, and if desired the enclosure 90 may bemodified in form to serve as a second hopper including a sliding plate structure for the control of hopper discharge as previously described .for plate 86 on hopper 42.

Figs. ll and 12 show trough-like track units which may replace the previously discussed parallel bar track form:

for handling unheaded work pieces which must be supported by the track bottom. Thus, for example, the form in Fig. ll is adapted to feeding nuts of. a given size, the width of the trough, which is integral with the baffles, being selected to correspond to the thickness of.

the nut. Likewise it may be used for bulk delivery of' small pieces, as to a weighing machine. or the like. The trough unit shown in Fig. 12 with a longitudinal partition provides two feed channels in the one track. This form is of advantage where the feeder is being used for packaging. work pieces, especially headless work pieces, by;

count rather than by weight in conjunction with a photoelectric counting device actuating a feed track discharge cut-off gate, for two streams of work pieces may be counted simultaneously thereby utilizing more fully the.

164 on the motor casing, and an eye plate 165 secured. to the upper end of track suspension spring 110, the track.

is linked to the motor to oscillate therewith. Predetermined looseness between hook 164 and the eye open ing in plate 165 produces. the advantageo-usquick movement of the track toward the motor at each revolution thereof. The lost motion prevents the motor from pushing the tracks on its return stroke, allowing return by the restoring force of the spring. plates 11*} and 115.

In Fig. 14 thefeeding mechanism 43 is shown adapted to handle short shank bolts, screws, rivets or other topheavy headed work pieces. mounted roughly parallel to the feed track in line with the feed track slot, is supported at one end by a bracket 117 hooked over the wall of housing 90 and at the other end in a speed reduction unit 172 pivotally mounted to the casing of driving motor 173 which is mounted at the which the bracket is hooked, provides a brush height adjustment for the accommodation of various work piece sizes. The brush bristles are grouped in tufts to allow the 5 A revolving brush 170,

g on the scale approaches the desired predetermined weight, the feed is automatically reduced just before that weight is reached, so that the correct weight of pieces is more readily measured. A second switch, operable after the first when the scale arm comes to full weight position, may serve to stop'the electromagnet and lift ring entirely to allow exchange of weighing containers.

The bottom of chute 291 may, as shown by the fragmentary detail in Fig. 29, be constituted of a plurality of corrugations providing channels disposed parallel to the length of the chute and the direction of feed. This type of chute bottom aids in disentangling the batch of work pieces dropped into the chute from each lift ring compartment. This chute structure, further, provides a pinrality of channels aligning work pieces into as many streams, an advantage when the feeder is used with a photo-electric counting device having a photo electric cell for each channel.

The lifting ring 46, rejector mechanism 100 and track assembly 97 have been described in the structures thus far disclosed as actuated by individual driving units. In Fig. 30, however, the lift ring, rejector mechanism and feed track are all belt driven from the ring driving unit. Here, instead of the track actuating system of Fig. 1 or Fig. 13, a pulley driven eccentric member linked to the spring mounted track by a rod is used to oscillate the track, though the conveyor belt track of Figs. 16-19 could be used. Where an eccentric type drive is used to oscillate the track, it should preferably be adapted in motion characteristics to draw the track opposite the feed direction quickly and with a high acceleration as compared to the return stroke speed and acceleration. The eccentric type track actuating unit of Fig. 30 shown in detail by the sectional view of Fig. 31 as hereinafter described, produces such track motion.

The structure of the mechanism of Fig. 30 is generally similar to that of Figs. 1 to and hence is not here described in detail apart from the specific points wherein it differs from the previous structures. Elements like to those in the other figures are designated by similar reference numerals. The driving unit 41 of the machine includes the motor 65 driving the triple sheave pulley 366 through belt 367, the pulley having one sheave driving the input pulley 368 of a variable speed reducing unit 369 through the belts 370, 371 and idler pulley 372, the other sheave driving the belt 373 for the rejector and track actuating units 30%), 343. The variable speed reducing unit output pulley 374 drives the lifting ring through belt 59 as in the structure of Figs. 1 to 4 and the hand wheel 76 controls the variable speed reducer to vary the lift ring speed independently of the speed of the simultaneously driven rejector wheel and track actuating units. The belt 373, which drives the pulley 376 of the track actuating unit and the double sheaved pulley 377 of the rejector wheel unit, is supported on one side of frame 45 by a pair of independent pulleys in a fixed belt supporting pulley block 378 and on the other side of the frame by the pulleys of a similar pulley block 379. In order to allow regulation of belt tension, the pulley block 379 is mounted on the arm 380 pivoted on the frame and provided with means for locking the pulley in a desired position.

The rejector unit 300 comprises a stud shaft 303 fixed in a bracket 304 attached to the frame 45, the double sheaved driving pulley 377 rotatable thereon, a rejector wheel support arm 305 having one end pivoted on' the stud shaft 303 and the other end bearing a stud shaft 306 on which the rejector wheel 135 rotates, the rejector wheel being driven from pulley 377 by a belt 142. Thus the wheel is pivotally mounted to swing upwards from the tracks when necessary. The clearance between track and the wheel is determined by an adjustable stop between the arm and bracket, the wheel being biased toward its lowermost position by its own weight.

The track structure, generally similar to that of Figs.

est tes 1-l0, having wings or bafiles, skirt shield, beveled pof= tions and apex near the rejector wheel, is secured to upper and lower leaf springs 310, 315 by mountings such as those shown in Figs. 7 and 8 for adjustment of the slot width. However, whereas in the previous forms the lower bar reaches 101b and 102b forming the discharge portion of the track assembly, which is inclined more steeply than the upper part of the track within the enclosure 90, are integral with the upper reaches carrying the baffles, here the lower reaches 301b and 302b below the spring 315 are separated from the upper reaches 301, 302 and are fixedly mounted to the frame 45.

The eccentric type actuating unit is seen more clearly in Fig. 31. The plate 320 extending from the frame 45 mounts a base 321 having an eccentrically bored extension 322 providing a stationary shaft and an eccentric bore 323 for rotatively mounting respectively, the driving pulley 376 and eccentric shaft 324 in non-coaxial relation. A pin 325 in the pulley, pin 326 in the end of shaft 324 offset from the shaft axis and'parallel to the first pin, and a connecting link or rod 327 tying the pins provide a mechanism whereby the pulley, rotating at constant rate rotates the eccentric shaft at a periodically varying rate. Snap rings 328 in the grooves on the pins hold the connecting rod 327 in place. On the end of the eccentric shaft opposite the link 327, the eccentric projection 329 with its axis coplanar, parallel and intermediate to the axes of the shaft and of the eccentric pin 326, provides a crank pin to which one end of the track connecting rod 330 is secured by a nut 331 threaded to the end of the eccentric projection. Preferably the connecting rod comprises two halves threaded one into the other and held by a lock nut to allow length adjustment. The other end of the track connecting rod 330 is pivotally secured as by the bolt 332 to an extension 333 rigidly secured to the track mounting structure on the leaf spring 310. By means of a shoulder 334 at one end and the link 327 at the other, the shaft 324 is held against axial displacement. As shown in the drawings, lubricating nipples and lubricating grooves and channels are provided in the rods 327, 330, extension 322, and pulley 376 and pins 325, 326 to lubricate the rotating surfaces.

With the described structure and with the axis of the eccentric bore 323 and hence shaft 324, displaced vertically downward from the axis of the pulley 376, the oscillatory or vibratory motion imparted to the track has the desired difierences in acceleration and velocity on the forward and rearward strokes of the track. The amplitude of track vibration is of course controlled by the degree of eccentricity of the eccentric extension or crank pin 329 relative to the axis of the shaft 324, while the difference in motion characteristics of the forward and rear stroke of the track is determined primarily by the amount of displacement of the shaft axis relative to the axis'of the pulley 376.

The lift ring unit described provides a structure adapted for rapid changes in lift rings for the accommodation of various type work pieces. With the trunnion-type ring mounting and removable end plates, the lift ring is readily accessible for removal and replacement by a lift ring having lifting compartments suited for a particular type of Work piece. Further, the end plate mounting is such that the end plates with attached hopper or feed discharge assembiy mounting structures are readily changed from one type of feed discharge track to another. Also, with the bolt and slot mounting of the end plate supporting the discharge track, the entire end plate with the discharge track mounted thereon may be rotated to some degree to provide for close positioning of the feed discharge point,

The lift ring and its enclosing structures and the feed discharge devices are such that jamming of work pieces is practically obviated. The pivoted suspension of the rejector wheel mechanism prevents jamming of work pieces or other objects beneath the wheel, while the spring suspension of the hold-down bar on the 1 W! 9 3% 1 chines. v

niembersewithin the lift ring,.with attendant nicking a nd sa a theffeeid discharge tracki allows the/bar: to be lifted nsane 7 u s ee i.@m',w i h;m sht 6 m em -bar li sr'ie k m 't b s e y pr-i s-zunho P e i of readjustmentr Abrasive materiah has little -iopper-; 7

tunity to; work between the lift ring and'the. frame and such fOreign niate'rial is a continually. separated from the a work pieces and discharged through the-skirts beneath the'feed tracks. By the elirninati nof-thelift-ringsup; porting axle usual 'in theprior art with itsioncomitant spider structuresextending radially toward :theliftring,

one source of prossible jam ningzofwork pieces is aveided and the entire machine is more compact than priorqna Further; churning of work pieces by support scarring thereoflis obviated} t e 7 7 With' the guide, wings, whether-separate or attached to inove with-the feed track, s et at an inclinationlless than the angle of free sliding for the workpieces, greater of the feed track outwardly beveled, misaligned work pieces in great part fall oil the track before reaching the :rejector wheelfsoi that a 'high rate of feed onto=the track win'gs'may be used without're'sulting in jamming at orioverloading of the rejector wheel; The low angle of flarehietween the guide wings reduces 'ricocheting of it he wo'rlg :pieces therefrom, resulting in a higherfpere 'centage of the pieces delivered by the liftflring' finding the track 7 having greater inclination.

;I claim: 7 I a a 7 ,u a I 1. Afeeder machineadapted 'toreceive workpieces in totprovideiadiustahility,

, 12' inthe 1Q11S39f discharges off said v feed disch'arge means.

A. feeder machine as descrihed-ingclaim; -z'having 7 the-said. lift-l ring' provided ;-w-ith{a secondfi'continuous the open: 'ends'of' rnoving 'cdrnpartinents-at the ascending position 'of the said 'lift ring, said-closure-rportionter nfl hulk andfto discharge-the same in a feed stream, cornp'rising'a rotationally driven lift ring with axishorizon tally disposed, the inner periphery of said ring-being" provided with spaced inwardlyextending partitions form- 7 "'ing worlg pieceliftingt cpmpartrnents, at least 'one en-d V of said ring having a continuous annulan end Wall -form-' j ihg an end closure for said compartinentsg a hou'singEen closing the circumference of said' ring and includingna pairof end plates disposed on opposite-ends of'said' ring;

' and maintaining the ring against -axial -displa cement,-fsaid a e a housing mounting a plurality of trunnion roller's for tion infclosevprokirnity toetheendj plate onywhich disch arge means f is-mounted; and "wherein a the last said "endplate is provided withran'openingjofivertical'd' en= Vportiofn." 1 a 7.: 'A' machine as described in claiml'with' guardrneans annular; end wall forming an end closurewfor the seve'ralj a said {compartments at. the ring end-oppesite the, first: said. J I

,annular end. wallvandhaving;anadjaeentaendiplate V V vided; with i r a circular shroud; flangereXtending ginv'vard 7 and overlying' the inner periphery of saidfsec'ond annular end wall ffto -shi'eld wthen adjacent-rend ipla'te -andvend awall surfaces from entrance of debris; Q5; theers'aidliftv ring provided: on' its. inner 'peripheryi-iwith atser'res' ofi spaced: slanted liftingblades'iasi' the. said partir' tionsi dividing theringiinto' said compartments andvvith a but one continuous annular end wallvadjacent the chopper- "supporting endjplate', 'the ends of :the 'compartments: op posi te said end wall being open; and, having'the othen d plate' formed-to provide an end-closurefiportion for nating abovsaiaifeed di'sGharge 'rn'aiisi-th direction ofs lant off said blades-bein closure-portion.

e 6: A machinei'asj described in *claiirn whereinfsaidl 5 3 discharge"means-extends p arallellto theplzine, of"'rot a-" the reed track slot These s'everalufeatures ffthe track; aiidg uide structure perniit-a'higherrate of delivery than fliasfbeen hitherto possible, particularly when the-fee track is oscillatedwiththe quicle'withdr awal and slower returns'troke motion produced by theydescribed track;

actuating units. Soa lso the f eedarate' forijphotoelectriq counting is increased by virtue of the spa'cin g developed betweeniwork pieces in passing onto the loweriportionofi t'i'on ofsai'd ringandfhas :an upper longitudinal' po 'si'on substantially the iinnerdiameter "of said rin g,

guard means preventing' work pieces-'projectingffrom "said 7' ring'ffrorn; engaging j the"'1inder "side of said; discharge fneans providediby a plate edg'efforrna'tion at 'said' open ing adjacent theasce'n'ding portion ofsaid ring:recejding inwardly relative "tof radii iof' said ring from *the bottom;

. provided'atfthe-opening of said'hopper' by an edge fo'rma- 'pe ripherally'{snpporting said lift ring, one'iofvsjaidy end plate's being; provided with a circular shroudixflange ex? tending inward and overlying the: inner periphery of i saidannularendwall of the lift ring; a hopper 'sti uct'ure" carried by the onel'of 'said end plates; having lther'said 4 1 shroud flange to"receive bulk"loaded workxp'iecesgand' having' anf outlet opening toethe'interior' ofsaidjliftjring" tdeliverwo'rk piec'es'tci said 'lift' ringjife'ecl discharge means mounted fo n one of the said end plates, said mea'ns, being" a'dapted t o' receive' work'pi'eces transported -fi'orn 'said ohtlet'hy'said na and to discharge'the'n in a continuous feed streamf and;driving means-engaging the outer periphery, of the ringif or rotating saidring about" said axis; I

" machine daniageaiidfjaniming upon obstruction ofiri'ng;

on. n- V r 31 A-n1fachine a'sdescribed' in' claim l'wherein thefe'nd ile iea i fiin a a nt v i e a d Pa -r a es? ias it -w platearnounting the-saidfeeddischarge-means is mounted mg portion 6f sa I ringl clirving inwardly.relative to; 1* hTnitd-lrotation relative to the: rest pf'ithe "housing' '1radii ogthefring fromrthe liottonfi otgsaid ppeningyto 1 r and extending-spanne 1051118 in; alift ring, said dischargenm eans 'havmgan upperqportiolrin--close;.proniniitydo'maidmthe end plate" andibe'ing 1 adapted tor ce e workp ec a po said; '7;

ousteed stream, saidfother endzplateha tion adjacentthe ascending-portion Qof saidting'receding einwa'rdlyurlativeftd radii of said'ri'ng from the bottom e toe-thedopfoftheaopehing for-preventing work: pieces 7 7' proiele'tingtro'rnfsaid "ring froni engagement'u unde r the? npperfedg'eof .saidihopperopening," I i V 711 f 7 7A1 feeder.machineQadapted torreceive workpieces j 8; in" hulkiand to dischargelihe" sarheli in .Vafeedjstream,

comprising a rotationally driven- 'lift fwith axis-hori-. zontally-zdisposed, the inneriperiphery ofsaid ring .being i i dew sn di nwa dlye nd s pe t ns orm ing wqrlepiece lifting compartmentsga housing-including i 7 7 ar rnd ip at s' sno scdom opppsite;e dsizof; said 7 ring;-and-maintainingithering-against:axialidisplacement; j a u,

said housi-n'g enclosing thecircumfereneezofsaid ring a i plura-lity of trunnion rollerseforiperiph ;.alshopperrstructure care ,toj receiveabulkrloaded work pieces and having anoutlet to the interior 'o'f said r liftarin'g-itd deliver; workil'pieces tossaid' lifti'ringtgfeed; 7

her; said ,end plate v l Of rot'ation ofg'said;

erall-y: supportin said 1 lift 2 ring; riediby, 'Ql'liioffsaili enctplate's,

discharge r'nie'ahsenlonnted on outlet by said; ring," and to ;discliargeithe1n in a' contin PIT): 7

Aafe'eder' machin'e as -descrihed inl claim" V V -suehj 'as-itofslgpe' down to-the l-as't'isaidfend plate when in thet as'cending"positionof9saida ,liftf i'ing, whereby f'saidcompartments flrnayr discharge through saidyopen ends' en"passingiabove thesaid end a I ofthe opening'to a'poinfabove said upper longitudinal,

a point at least the height of the said upper portion of the discharge means proximate thereto, whereby work pieces projecting from said ring are displaced back to the ring to prevent jamming engagement with said discharge means; and driving means engaging the outer periphery of the ring for rotating said ring about said axis.

9. A feeder machine adapted to receive work pieces in bulk and to discharge the same in a feed stream, comprising a rotationally driven lift ring with axis horizontally disposed, the inner periphery of said ring being provided with spaced inwardly extending partitions forming work piece lifting compartments; a housing including a pair of end plates disposed on opposite ends of said ring and maintaining the ring against axial displacement, said housing enclosing the circumference of said ring and mounting a plurality of trunnion rollers for peripherally supporting said lift ring; a hopper structure carried by one end plate to receive bulk loaded work pieces and having a bottom outlet opening through said one end plate to the interior of said lift ring to deliver work pieces to said lift ring; guard means at said outlet comprising an edge formation bounding said opening in the region adjacent the ascending portion of said ring and curving inwardly relative to radii of said ring from bottom to top of the opening, for displacing projecting work pieces back into the ring to prevent work piece engagement under the upper boundary of said opening; feed discharge means mounted on one of the said end plates, said discharge means being adapted to receive work pieces transported from said outlet by said ring and to discharge them in a continuous feed stream; and driving means engaging the outer periphery of the ring for rotating said ring about said axis.

References Cited in the file of this patent UNITED STATES PATENTS 459,698 Buifum Sept. 15, 1891 973,921 Dodge Oct. 25, 1910 1,086,429 Wetmore Feb. 10, 1914 1,104,029 Weiss July 21, 1914 1,254,157 Perkins Ian. 22, 1918 1,326,925 Goldberg Jan. 6, 1920 1,476,064 Eynon Dec. 4, 1923 1,600,238 McCain Sept. 21, 1926 1,637,401 Weyandt Aug. 2, 1927 1,687,134 Lynch et al Oct. 9, 1928 1,764,607 Cook June 17, 1930 1,784,124 Wilcox Dec. 9, 1930 1,858,328 Heymann et a1. May 17, 1932 2,015,892 Greenlaw Oct. 1, 1935 2,203,287 Smith June 4,- 1940 2,337,667 Kuehlman Dec. 28, 1943 2,531,099 Anderson Nov. 21, 1950 2,549,322 McKinsey Apr. 17, 1951 2,613,374 Gora Oct. 14, 1952 2,621,824 Gookin Dec. 16, 1952 2,636,319 Knight Apr. 28, 1953 2,667,797 Buenger Feb. 2, 1954 2,683,487 Conner July 13, 1954 2,696,285 Zenlea Dec. 7, 1954 

